12

W

E HAVE SEEN HOW QUANTUM MECHANICS provides tools for

understanding some simple systems, up to and including the hydro-

gen atom itself. An understanding of the H atom is a crucial point because it

is real,not a model system. Quantum mechanics showed that it can describe

the hydrogen atom like Bohr’s theory did. It also describes other model sys-

tems that have applications in the real world. (Recall that all of the model

systems—particle-in-a-box, 2-D and 3-D rigid rotors, harmonic oscillators—

could be appliedto real systems even if the real systems themselves weren’t

exactly ideal.) As such, quantum mechanics is more applicable than Bohr’s

theory and can be considered “better.” We will conclude our development of

quantum mechanics by seeing how it applies to more complicated systems:

other atoms and even molecules. What we will find is that explicit, analytic

solutions to these systems are not possible, but quantum mechanics does

supply the tools for understanding these systems nonetheless.

12.1 Synopsis

In this chapter, we will consider one more property of the electron, which is

called spin. Spin has dramatic consequences for the structure of matter, con-

sequences that could not have been considered by the standards of classical

mechanics. We will see that an exact, analytic solution for an atom as simple

as helium is not possible, and so the Schrödinger equation cannot be solved

analytically for larger atoms or molecules. But there are two tools for studying

larger systems to any degree of accuracy: perturbation theory and variational

theory. Each tool has its advantages, and both of them are used today to study

atoms and molecules and their reactions.

Finally, we will consider in a simple way how quantum mechanics con-

siders a molecular system. Molecules can get very complicated. However, we

canapply quantum mechanics to molecules. We will finish this chapter with

an introduction to molecular orbitals and how they are defined for a very

simple molecule, H 2 . Simple as this system is, it paves the way for other

molecules.

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12.1 Synopsis

12.2 Spin

12.3 The Helium Atom

12.4 Spin Orbitals and the
Pauli Principle

12.5 Other Atoms and the
Aufbau Principle

12.6 Perturbation Theory

12.7 Variation Theory

12.8 Linear Variation Theory

12.9 Comparison of Variation and
Perturbation Theories

12.10 Simple Molecules and the
Born-Oppenheimer
Approximation

12.11 Introduction to LCAO-MO
Theory

12.12 Properties of Molecular
Orbitals

12.13 Molecular Orbitals of Other
Diatomic Molecules

12.14 Summary

Atoms and Molecules